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INVENTOR. ELL S. MILLER United States Patent O 3,236,150 SCREENS FOR PROJECTING SYSTEMS Wendell S. Miller, 1341 Comstock Ave., Los Angeles 24, Calif.

Original application, July 23, 1956, Ser. No. 599,376, now Patent No. 2,974,564, dated Mar. 14, 1961. Divided and this application Feb. 13, 1961, Ser. No. 88,889

The present invention reates to improved screens useful in the projection of either still or motion pictures and has particular applicability in those instances where it is desired t-o view projected pictures in rooms or areas, such as drive-in theatres, wherein the ambient light intensity is otherwise prohibitively high and in this respect, the present invention is considered to be an improvement in the systems described and claimed in my copending application, Serial No. 485,987, filed February 3, 1955 now Patent No. 2,974,565, in that in the use of the present arrangement, the projection screen is coated with a protective coating, and the optical system is so arranged that refiecti-ons from such protective coating do not enter the field of view. The present application is a division of my copending application, Serial No. 599,376, filed July 23, 1956, now Patent No. 2,974,564.

In general, the present system involves a multifacet screen covered with a protective coating with means for supporting such screen at an angle inclined to the axis of a projected beam and a light absorbent structure which absorbs that ambien-t light that otherwise might be reflected into the viewing area from the direction of the screen, the screen being useful either for light reflection or for light transmission, as illustrated herein.

An object -of the present invention is, therefore, to provide an improved screen for projection systems of the character indicated above, using a protective coated screen tha-t may be used either for light transmission or light reflection.

A specific object of the present invention is t-o provide a screen for a system of this character in which the screen consists of a plurality of light reflecting elements, each arranged to refiect a corresponding portion of the image which is focused on the screen.

Another specific object of the present invention is to provide a screen for a system of this character in which the refiecting screen consists of a plurality of reflecting facets, each of which is arranged to reflect into the viewing area a corresponding portion of an image which is focused on the screen, the picture being projected generally along an axis which is inclined with respect to the general plane of the screen. I

Another specific object of the present invention is to provide a screen for a system of this type in which a focus screen consisting of a plurality of reflecting facets is inclined both with respect to the projection axis and the viewing axis, with such facets arranged to reflect light in accordance with one form of the present invention and to transmit light in a different form of the present invention into the viewing area from a predetermined area which includes the projection axis, with provisions, however, in such area for absorbing that light which otherwise might result in dilution of the picture that is being projected along said projection axis.

Another object of the present invention is to provide an improved screen for a projection system of this type with provisions for moving the screen to enhance the picture quality.

Another object of the present invention is to provide lan improved projection screen involving a plurality of 3,236,150 Patented Feb. 22, 1966 facets covered with a smooth protective coating that is easily cleaned for picture transmission or picture reliection, as the case may be.

Another object of the present invention is to provide an improved screen having a novel shape and arrangement of facets thereon for achieving improved results.

Another object of the present invention is to provide an improved screen for a projection system of this character in which the individual facets on the screen are so shaped as to allow the use of a protective coating over the same.

Another object of the present invention is to provide an improved screen for a system of this character incorporating a smooth outer surface which may be easily cleaned in association with specially shaped and disposed facets underneath the protective surface so that the facets underneath the protective surface refiects incident thereto in-to a region outside of the viewing area.

The features of the present invention which are believed to be novel are set forth with particularity in the appended claims. This invention itself, both as to its organization and manner of operation, together with further objects and advantages thereof, may be best understood by reference to the following description taken in connection with the accompanying drawings, in which:

FIGURE 1 illustrates a section through a projection system embodying features of the present invention.

FIGURE 2 is a view in elevation showing a portion of the front of a projection screen illustrated in FIG- URE l.

FIGURE 3 illustrates a modified form wherein the screen illustrated in FIGURE 1, instead of being mounted stationary, may be vibrated.

FIGURE 4 illustrates generally that field or area from which light may be reliected from an individual facet of a composite screen illustrated in FIGURE 1 into the viewing area and serves also to illustrate generally the area into which the light from the protective face is reflected.

FIGURES 5, 6 and 7 are sectional views taken respectively on corresponding lines 5 5, 6--6 and 7 7 of FIGURE 2.

FIGURE 8 is a perspective view showing a portion of the facet structure of the screen illustrated in the previous figures.

FIGURE 9 illustrates another modified arrangement wherein a screen having a structure illustrated in previous views is used as a light transmitting element.

FIGURE 10 illustrates another modified arrangement embodying features of the present invention.

FIGURES 1l and l2 illustrate still another modified form of the present invention; FIGURE 12 being a view taken generally Ion the line 12-12 of FIGURE 11.

FIGURE 13 illustrated still another modified form of the present invention using a screen which is more curved than that screen illustrated in FIGURE 12.

FIGURES 14, 15 and 16 illustrate other facet shapes and arrangements that may be used in the screens illustrated in the lprevious figures, with the exception of FIG- URE 10, it being noted that FIGURE 15 is a sectional View taken substantially on the line 15-15 of FIGURE 14; and FIGURE 16 is a perspective of a portion of the facet structure.

FIGURE 17 is a perspective view similar to that illustrated in FIGURE 8 and is also used in accordance with features of the present invention. In this case, the facets illustrated in FIGURE 17 have a greater overhanging portion at their junction than is the case in FIGURE 8.

FIGURE 18 is a view similar to FIGURE 17 showing an attached coating.

FIGURE 19 is a view similar to FIGURE 4 illustrating the relationship of some of the corresponding ray paths in the presence of an attached coating.

As illustrated in FIGURE l, the `opti-cal system includes a projection system which is illustrated herein as a motion picture projector 1li and serves to project a picture onto a mirror 11 which may be plane but which is preferably shaped to minimize or eliminate astigmatism and curvature field so that the same may be reflected onto the screen 12 in focus for the general purpose of projecting pictures in the general area indicated by the numeral 22. For example, the mirror 11 may be cylindrical, elliptical or it may be a prism instead. Also, if desired, the correction may be introduced into the system by predistorting the pictures in the frames of the movie film A such that the picture as viewed by a viewer in the area 22 sees an undistorted picture.

It is understood that instead of a motion picture camera 10, a projector of still pictures, television pictures or other types may be used and in each case, the projector may be positioned to project pictures directly onto the screen 12 without the aid of the reflecting mirror 11. In other words, the projector 10 may be positioned at the virtual image point of the mirror 11 on an extension of the central light lbeam 14 which is understood to represent the main or central projection axis. It is observed that this projection axis 14 is inclined with respect to the general plane `of the screen 12. Such screen 12, as shown in FIGURE 1, is pivotally mounted in an adjusted position on the bracket 15 which extends downwardly from the stationary supporting structure 16 at an angle with the vertical of approximately fifty degrees (50) as indicated. It is noted also that the viewing axis corresponds generally to the line 18, this line 18 also being inclined with respect to the general plane of the screen 12 and such line 18 serves to indicate the central position of those light beams which are reflected onto the viewing area or field 22.

In accordance with an important feature of the present invention, as contrasted to the arrangement shown in my above mentioned copending application, the screen 12 is provided with an outer protective plane surface 12B which may be easily cleaned and under which a plurality of specially designed facets 12A are disposed under protection of the outer surface 12B.

It may be noted that the term facet as used in this application refers to a substantially specular lenticulation having curvature of the same sense in each of two mutually perpendicular directions as illustrated by the typical example in FIGURE 4.

In general, the facets 12A are so shaped and disposed that they direct elemental portions of the projected picture into the viewing area 22, while the smooth protective coating7 12B serves to direct light (either ambient or light from the projector) reflected therefrom into an area outside of the viewing area 22.

In FIGURE 1, it is understood, of course, that some of the light from the projector 10 is transmitted through the protective coating 12B onto the facets 12A from where such light is reflected into the viewing area 22. On the other hand, some of the light, either ambient or light from the projector 10, is refiected from the surface 12B and a -distinction is thus made between that light which is reflected from the facets 12A and that light which is reflected from the protective coating 12B. In accordance with features of the present invention, the light reflected from the facets, on the one hand, and from the protective coating 12B, on the other hand, is reflected into different areas. For that purpose, the facets 12A are shaped as shown, particularly with reference to FIGURE 7, such that no portion of a particular facet 12A has a surface which extends parallel with the surface of the protective coating 12B. Preferably, as shown, these facets 12A, as as seen in cross-section in FIGURE 7, appear as a series of sawteeth, with each facet being generally rectangular as illustrated in FIGURE 8 and being defined in crosssection by portion 12C that extends generally perpendicular to the plane of the protective coating 12B and with a curved, arcuate or concave portion 12D, `contiguous with the portion 12C. The shape of the horizontal and/or vertical cross-section portion 12D may, in a special case, be defined mathematically in accordance with the following mathematical equation: y=1/c loge cos cx, where c may lbe equal to 1. In a plane containing a reflecting element described by this equation, the angle which the tangent to the surface in this plane makes with the x axis of the plane is proportional to the abscissa of the curve at the tangent point. This means that beams of parallel light of uniform intensity are reflected with equal intensity in those directions in which they are reflected from such a surface.

Preferably these facets, as illustrated in FIGURE 8, have a projected area which is generally rectangular as illustrated in FIGURE 8 for ease of manufacture so that the longer dimension of the rectangle extends in the hori- Zontal plane to thereby provide a corresponding viewing field which extends a greater angle in the horizontal direction than in the vertical direction. However, these facets may be so shaped that keystoning the shape of the viewing field cone is avoided so that the viewing cone extending from point 48 (FIGURE 4) through field 22 is of such shape as may be desired. Indeed, the facets, instead of being identical, may be in the form as illustrated in connection with FIGURES 14, 15 and 16, wherein the facets of the screen 112 comprise a series of trapezoidal shaped facets 112A, 112A which, when arranged in adjacent side-by-side relationship provide along the line 15-15 of FIGURE 14 the continuous undulatory path 112B of FIGURE 15. For this purpose, the facets 112A have a convex outer surface, and the facets 112A have a concave outer surface that blend together as illustrated in FIGURE l5. The reflecting surface of the facets of the screen 112 is also protected by a plane protective coating and the facets 112A and 112A each has a reflecting surface, no elemental portion of which exten-ds parallel with the plane of the plane protective surface to achieve the results indicated above in connection with the discussion of facet 12A. One of these facets 12A is illustrated in a three-dimensional representation in FIGURE 4, the corners thereof being designated as A, B, C and D, and these letters correspond to the same corners illustrated in FIGURE 2.

Each of these facets 12A is capable of reflecting light which may be directed at it from the field or area represented by the shaded area 20 in FIGURE 4 and to reflect some of such light from such field 2f) into the solid cone of the viewing field defined by the point 48 and the shaded area or field 22. Such reflection is from the surface of the individual facets from planes tangent to the outer surfaces, i.e., in a substantially specular manner. One of such tangent planes is represented in FIGURE 4 by the line P which is tangent to the face of the facet at point E. There is also indicated in FIGURE 4 by the extension of the line 4S through point E, the principal beam of the projected light source represented by the line 14. As a matter of fact, the only light which may be reflected into the viewing area 22 from the facet 12A is that light which may be derived from the shaded area 20. This area 20 is preferably covered with light absorbing material so that the only light which enters the viewing field is that light being projected by the projector. This means that when the screen 12 is not being illuminated by 4the projector, the screen 12 appears dark to a viewer in the viewing field 22 even though the ambient light intensity is relatively high.

The reflecting surface of each facet 12A (112A and 112A in FIGURES 14-16) is related to the plane of the protective surface 12B, as described above, so that any light reflected from the protective surface 12B is directed into an area outside of the field of View. As illustrated in FIGURE 4, light traveling in the direction indicated by the line 14 and reflected from the surface 12B, for example, is flected in the direction indicated by the line 14A into an area other than the area 22. The particular area from which light may come to be reflected by the protective surface 12B into the viewing cone is so treated to absorb ambient light. This area may be coextensive with the area 20, overlap the area 20 or be outside of the area 2t), so long as the light reflected from the face 12B does not enter the field of View 22, established by the particular shape and disposition of the facet 12A.

It is understood that each of the facets or elements 12A (or facets 112A and 112A) serves to reflect into field 22 the corresponding elemental portion of the image of the entire picture which is being focused by the projector 1t) von that particular facet. In other words, these elemental ing the facet size relatively large (i.e., improve the quality or appearance of the viewed picture so that the same does not appear to be a composite Iof elemental portions) the screen 12 or 112) as a whole may be oscillated through a relatively small distance in the plane of the screen at a frequency such that the apparent transverse movement of a spot of refiected light coming from each facet is obscured by persistence of vision. Thus, means may be provided for oscillating the screen 12 in its plane, as shown in FIGURE 3.

It is observed that the area 20 is relatively large, being much larger than the area defined by the light beam from the projector and for that reason, under usual conditions of ambient light, would be capable of supplying more illumination to the screen than the projector. In accordance with important features of the present invention, such area corresponding to the area comprises the area of light absorbing material. Thus, the area of the projected beam is defi-ned generally in FIGURE l by the outside lines 24 and 25 which extend between the mirror 11 and the screen 12. This area 24, 25 thus defined, is much smaller than the area 20 represented in FIGURE 4. While the projected beam passes through such area 20, the remaining portion `of such area 20 is lined with light absorbing material as, for example, the light absorbing material 26 on the face of the vertical wall or baffle 27, the light absorbing material 26 on the horizontal extending apertured stationary member 28 and the light absorbing material 26 on the other vertical extending wall 29. It is noted that the light bafiie 13 is also lined with light absorbing material 26 since, optically speaking, the same may be considered to define a portion of the area 20. This is particularly obvious when no mirror 11 is being used.

It is a-pparent that the vertical bafiies 27 and 29 may be omitted but in such case, a correspondingly greater portion of the horizontal extending bafiie 28 must be covered with light absorbing material 26. Also, instead of bein-g vertical, these baffles 27 and 29 may extend upwardly at any other angle so long as their upper edges intercept the lines 41 and 40, respectively. The effect of the'bafiies 27 and 29 is4 to render the system more cornpact. The baflie 29 extends upwardly a sufficient height so as not to block out the light, however, which is being reflected from the facets 12A into the viewing area which is being reflected from any one of the facets 12A into the viewing area 22. These baffles 27, 29 also encompass the area which receives light that is reflected from the outer protective face 12B, regardless -of where such light may originate; i.e., for example, ambient light from the viewing field or light from the projector lilxitself.

In other words, that area generally within the limiting lines 40 and 41 should be covered with light absorbing material so that there is minimum refiection of ambient light which otherwise might produce dilution of the image; i.e., impair the contrast in the viewing area or field 22.

This field 20, thus defined by the lines 40 and 41 in both FIGURES 1 and 4, is referred to generally as the field 20 of interfering light but it is within this field and through this field that the lbeam 14 is projected.

The relationship `between the fields 2G and 22 may be determined graphically, knowing the dimensions and curvature of the facet 12A and observing the optical rule that the angle of incidence as measured from the normal to a reflecting surface is equal to the angle of refiection from the normal to such a surface. FIGURE 4 is drawn for the special case of convex spherical facets, in which case the center of curvature of the reflecting surface is designated by the point 46 and the radius of curvature is designated by the line 48A. A similar diagram may be constructed for facets of other shapes by applying the law of reflection to the surface of the facet at each of its surface points in turn. The term specular is commonly used to identify facets characterized by this law of reflection, as distinguished from those provi-ding randomly oriented or diffuse reflection.

The virtual image point in the spherical reflecting facet 12A is designed by the point 48 at which the lines 50, 51, 52 and 53 converge, also. In any case, these lines 50, 51, 52 and 53 define the outer points of the viewing field 22 and pass through corresponding edges of the facet 12, as shown. I

The field or area 20 is defined generally in like manner by lines 40, 40A, 41 and 41A, each converging at the point 60 and passing through corresponding edges A, B, C and D of the facet 12A.

As illustrated in FIGURE 3, the screen 11 is moved in its -plane by a motor-driven cam arrangement which cornprises a disc 70 affixed to the motor shaft 72. A link 74 is pinconnected at opposite ends thereof to the disc 70 and the screen 12. The link 74 is pivotally mounted on pin 84 and the pin 86 serves to rigidly connect the link to the screen. The screen 12 is resiliently mounted in a stationary framework including the stationary elements 77-81 by spring means 82. Thus, as the motor shaft 72 rotates, the screen 12 is loscillated in both the horizontal direction as well as in the vertical direction to improve the quality of the viewed picture when the facet size is large as mentioned above.

The field of view may be maximized and other advantages accrue when, as illustrated in connection with FIG- URES l1, 12 and 13, the screens 212 and 312 shown therein are curved.

For purposes 4of definition, the field of total view is defined as the intersection of the individual fields of view of all of the facets; i.e., the logical product, whereas the field of interfering light is the join of the fields of interfering light of all of the facets, a join being the logical sum.

By curving the screen, the field of total view is increased and curving also reduces the field of frontal refiection; i.e., the field from which light is reflected from the front smooth protecting layer into the field of total view. Also, it is easier optically to project onto a curved screen than on a fiat screen because less correction and/or Petzval curvature, as the case may be, is required of the projection lens. In the arrangement shown in FIGURES 11, 12 and 13, the facets have the same general shape as previously described in connection with FIGURE S or FIGURE 14. An optimum condition is considered to be achieved when the axes of the viewing cones from each of the facets are parallel, asA indicated by the parallel lines and 101. In this case, the angular spread of the field of view is maximized and is equal to the angle of the individual facet fields of view.

As the curvature is increased, as shown in FIGURE 13, the width of the field of view at extreme depths is reduced. The field of view in FIGURE 12 is bounded by the lines 20B and 20C which represent the edges of a cone. The point 220A in FIGURE l2 represents the center of curvature of the screen 212 and the point P represents the center of projection. It is noted that by increasing the curvature beyond the optimum condition illustrated in FIGURE l2, the vertex point of the field of view is extended forwardly toward the screen. This vertex point of field of view is represented by the point 20A in FIGURE 1, also, by the point 220 in FIGURE 12 and by the joint 320A in FIGURE 13. In FIGURE 13, the center of projection is the point P and the center of curvature is the point 220B; and the field of view is defined by the lines 20D, 20E, 20F and 20G.

Thus, as illustrated in FIGURE 13, by further increasing the curvature of the screen beyond that required to produce the optimum condition shown in FIGURE 12 in which the axes of the fields of view of the individual facets are parallel, the axes of the individual fields of view may be made to converge in front of the screen. In this case (i.e., FIGURE 13) the apex point 320A of the field of. total view is moved closer to the screen for the same position of the projector and facet shape. However, this effect is accomplished at the expense of the angular width of the field of total View at a great distance from the screen. Thus, in FIGURE 13, the field of total view which would be defined by the lines 20D and 20E is further truncated by the lines 20F and 20G. This loss of field `at great distance will usually prove to be a small sacrifice to pay for the increased viewing area near the screen occasioned by this configuration.

In both cases represented in FIGURES 12 and 13, the viewing area is increased over that which is obtainable using a fiat screen in the same configuration.

In the modified arrangement shown in FIGURES 9 and 10, the same principle is used to enhance the contrast of a transmission screen system by so arranging the screen that ambient light is prevented from being reiiected into the viewing field of the system by the surface of the screen towards the audience.

Thus, in the modified arrangement shown in FIGURE l0, a projection system is used in which the projector 410 is disposed behind the inclined screen 412 which has a ground glass back surface 412A. The plane of the transparent screen 412 is inclined with respect to the horizontal projection axis 411 which is coextensive with the viewing axis 411A. The screen 412 is so inclined that all light passing tothe field of view after refiection at the front planar surface 412B must have come from the area or region 415 which is covered with light absorbing material 416. The screen is, however, so arranged that light may be transmitted through the screen into the field of view after being focused on the back surface 412A of the screen. The screen 412 may be light absorbing itself so that light from the direction of the viewing field suffers some double adsorption (i.e., travels through twice the thickness of the screen 412 before being reflected into the light absorbing area 415. One of the novel features in the arrangement shown in FIGURE involves the concept of tipping the transmission screen 412 and the provision of the light absorbing area 415). The projector 410 in FIGURE l() is enclosed in a light tight enclosure 417 of which the screen 412 provides a side.

In the modified arrangement illustrated in FIGURE 9 which is related to FIGURE 10, a dierent form of transmission screen is used. The screen in FIGURE 9 incluudes lenses either concave or convex, preferably concave lenses, so arranged that the light that would be reflected into the viewing area must have come from the blacked-out area. These lenses (which in this case are the elements which I, otherwise, refer to as facets) illustrated in FIGURE 8, may be covered with a transparent smooth film or surface 412. In all those arrangements wherein facets are used, either the square facets as illustrated in FIGURE 8 or FIGURE 17, or the trapezoidal facets, as illustrated in connection with FIGURES 14-16, may be used. The trapezoidal facets are preferred to minimize or eliminate keystoning of the field. In using a square facet, the boundary defining a section through the field of view normal to the viewing axis is trapezoidal when, as illustrated, a rectangular facet is connected with respect to the field of view. By using trapezoidal facets, the boundaries of the section through the viewing field normal to the viewing axis may be made rectangular or, indeed, may be shaped as desired, depending upon the outline of the trapezoidal facets.

As mentioned previously, the provision of the smooth transparent protective layer 12B introduces a surface from which objectionable frontal reflections may occur. It is understood that while the drawings, for purposes of simplicity, illustrate the protective layer 12B as being a fiat strip, it is understood that the protective layer may be of clear plastic material, for example, which presents a smooth outer surface for ease of cleaning, with the plastic material filling the interspaces between the refiecting facets as illustrated in FIGURE 18. In this figure, 12B is the same as the coating material 12B of FIGURE 7 but in this attached configuration. While in the arrangement shown in FIGURE l, the light due to frontal refiection from the surface 12B is directed into the field of interfering light defined by the light absorbing material 2d, the field of interfering light and the field in which light from frontal refiections are directed need not necessarily be coextensive or overlap. Indeed, the screen 12 in FIGURE l, for example, may be tilted so that it makes a lesser angle with respect to the vertical than the 50 angle illustrated in FIGURE l, so that the light from frontal reflections is directed into an area which lies above the field of view 22. In this latter instance, a light trap; i.e., a light absorbing area, may be disposed to receive such light from frontal reflections for absorbing the same.

Further, it is understood that the front surface of the protective coating 12B does not necessarily have to be completely planar so long as it satisfied the conditions for preventing the reflection of undesired light in the viewing field as described previously and, indeed, may also have curvature as illustrated in connection with the protective and easily cleaned front transparent surfaces in FIGURES 12, 13 and 19. Further, as shown in FIG- URE 19, it is noted that the light which is reflected from the facets travels through twice the thickness of the protective transparent cover or layer 12B and its index of refraction aids in extending the field of View. Thus, the plastic material may be used having, for example, an index of refraction of 1.5 which means that a ray of light entering the plastic layer is bent in its travel towards a refiecting facet and also, the same ray after reflection from the facet is bent after it leaves the protective layer. The exit path of this ray is shown at 114. This has the general effect of allowing the use of a fiatter facet than is otherwise the case when the protective layer of index of refraction greater than 1 is omitted,

While the particular embodiments of the present invention have been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made without departing from this invention in its broaderaspects and, therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of this invention.

I claim:

1. A screen comprising a plurality of substantially specular facets of generally trapezoidal shape, with one of the parallel sides of said trapezoids being larger than the other, said facets each belonging to one only of two distinct classes, facets of one of said classes having positive curvature and facets of the other of said classes having negative curvature, facets of said two classes being intermingled on the face of said screen in essentially checkerboard fashion, said facets being so oriented on the face of said Sreen that those of one class have the References Cited by the Examiner UNITED STATES PATENTS 1,535,985 4/1925 Clark 88-289 1,550,880 8/1925 Clark 88-289 1,806,864 5/1931 Pallemaerts 88-28.9

Shimizer 88-2893 Moller et al. 88-289 Kellogg 88-28-93 Cuneo 88-24 Barth 88-24 Mihalakis 88-289 Grossman 88-289 Mihalakis et al. 88-289 FOREIGN PATENTS Great Britain.

JULIA E. COINER, Primary Examiner. WILLIAM MISIEK, Examiner. 

1. A SCREEN COMPRISING A PLURALITY OF SUBSTANTIALLY SPECULAR FACETS OF GENERALLY TRAPEZOIDAL SHAPE, WITH ONE OF THE PARALLEL SIDES OF SAID TRAPEZOIDS BEING LARGER THAN THE OTHER, SAID FACETS EACH BELONGING TO ONE ONLY OF TWO DISTINCT CLASSES, FACETS OF ONE OF SAID CLASSES HAVING POSITIVE CURVATURE AND FACETS OF THE OTHER OF SAID CLASSES HAVING NEGATIVE CURVATURE, FACETS OF SAID TWO CLASSES BEING INTERMINGLED ON THE FACE OF SAID SCREEN IN ESSENTIALLY CHECKERBOARD FASHION, SAID FACETS BEING SO ORIENTED ON THE FACE OF SAID SCREEN THAT THOSE OF ONE CLASS HAVE THE LONGER OF THEIR PARALLEL SIDES POSITIONED TOWARD ONE DIRECTION ON SAID SCREEN, AND FACETS OF THE OTHER CLASS HAVE THE LONGER OF THEIR TWO PARALLEL SIDES POSITIONED TOWARD AN OPPOSITE DIRECTION ON SAID SCREEN, 